A nonvolatile memory and a data rewriting method of the nonvolatile memory that can readily detect a state of operation at a time of a system failure due to a power failure or the like and quickly and reliably restore the nonvolatile memory to a normal storage state by a simple method. In the nonvolatile memory including a physical block as a storage unit, the physical block having a data area (1) and a redundant area (2), the redundant area (2) includes: a logical block address storing area (3) for storing an address of a corresponding logical block; a previously used physical block address storing area (4) for storing an address of a physical block to be erased; and a status information storing area (6) for storing status information for distinguishing a state of operation in each stage occurring in performing data rewriting operation on the physical block.
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1. A nonvolatile memory comprising a physical block as a storage unit, said physical block having a data area for storing data and a redundant area for storing various management information,
wherein each said redundant area includes:
a logical block information storing area for storing information for identifying a logical block corresponding to a physical block including said redundant area;
a previously used physical block information storing area for storing information for identifying a previously used physical block, which is an immediately preceding physical block with which the corresponding logical block was associated; and
a status information storing area for storing status information for distinguishing a state of operation in each stage occurring in performing data rewriting operation using the physical block including said redundant area for data writing; and
wherein said status information storing area stores at least first status information indicating that the physical block including said status information storing area is in an erased state, second status information indicating that while data writing to the physical block including said status information storing area is completed, data of the corresponding previously used physical block is not erased, and third status information indicating that data writing to the physical block including said status information storing area is completed and that the data of the corresponding previously used physical block is erased.
3. A nonvolatile memory data rewriting method for rewriting data in a nonvolatile memory, said nonvolatile memory including a physical block as a storage unit, said physical block having a data area for storing data and a redundant area for storing various management information, said data rewriting method comprising:
a first step for determining a logical block for data rewriting;
a second step for determining a physical block for data writing from among empty blocks, which are erased physical blocks allowing writing;
a third step for identifying a previously used physical block, which is a physical block associated with the logical block for rewriting, by referring to an address conversion table for associating the logical block with the physical block;
a fourth step for writing data to the physical block for writing;
a fifth step for erasing data from the previously used physical block; and
a sixth step for updating the address conversion table such that the physical block for writing is associated with the logical block for rewriting;
wherein in the physical block for writing, first status information indicating that the physical block for writing is in an erased state is set initially, second status information indicating that the writing of the data is completed is set after completion of processing at the fourth step, and third status information indicating that the erasure of the data from the previously used physical block is completed is set after completion of processing at the fifth step.
7. A nonvolatile memory data rewriting method for rewriting data in a nonvolatile memory, said nonvolatile memory including a physical block as a storage unit, said physical block having a data area for storing data and a redundant area for storing various management information, each said redundant area having a status information storing area for storing status information for distinguishing a state of operation in each stage occurring in a physical block for writing in performing data rewriting operation, said data rewriting method comprising:
a first step for determining a logical block for data rewriting;
a second step for determining a physical block for data writing from among empty blocks, which are erased physical blocks allowing writing;
a third step for identifying a previously used physical block, which is a physical block associated with the logical block for rewriting, by referring to an address conversion table for associating the logical block with the physical block;
a fourth step for writing data to the physical block for writing;
a fifth step for erasing data from the previously used physical block; and
a sixth step for updating the address conversion table such that the physical block for writing is associated with the logical block for rewriting;
wherein the second step includes:
a seventh step for determining a number of empty blocks; and
an eighth step for generating a random number, selecting one empty block from among a plurality of the empty blocks, and determining the empty block as a physical block to be written.
2. The nonvolatile memory as claimed in
wherein the first status information, the second status information, and the third status information are represented by an identical number of bits; and
the second status information is formed by changing binary data of one or a plurality of bits in a bit string representing the first status information from“1” to“0”. and the third status information is formed by changing binary data of one or a plurality of bits in a bit string representing the second status information from“1” to “0”.
4. The nonvolatile memory data rewriting method as claimed in
wherein the first status information, the second status information, and the third status information are represented by an identical number of bits; and
the second status information is formed by changing binary data of one or a plurality of bits in a bit string representing the first status information from“1” to“0,” and the third status information is formed by changing binary data of one or a plurality of bits in a bit string representing the second status information from“1” to“0.”
5. The nonvolatile memory data rewriting method as claimed in
wherein the second step includes:
a seventh step for determining a number of empty blocks; and
an eighth step for generating a random number, selecting one empty block from among a plurality of the empty blocks, and determining the empty block as a physical block to be written.
6. The nonvolatile memory data rewriting method as claimed in
wherein an empty block registration table including a plurality of storage units sequentially arranged so as to correspond in number with the empty blocks is provided, each of the storage units storing information for identifying an empty block; and
the empty block to be written is determined by selecting one of the storage units in the empty block registration table according to the generated random number.
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The present invention relates to a nonvolatile memory and a data rewriting method of the nonvolatile memory that can detect a defective data block and restore the data block to a normal storage state at a time of a restart after a system failure due to a power failure or the like occurs in the nonvolatile memory such for example as a NAND-type flash memory provided in an electronic device such as a memory card or the like.
Low-cost nonvolatile memories such as for example NAND-type flash memories suitable for storing a large amount of data have recently been widely used in household electrical appliances, portable electronic devices, and electronic devices such as memory cards and the like. When a system failure caused by a power failure, a malfunction or the like occurs in an electronic device having a flash memory, for example, part of data stored in the flash memory can be destroyed. As one method for protecting data from such a system failure, redundancy is provided to data written to the flash memory using a check sum or CRC (Cyclic Redundancy Check) code, for example, and a check sum is calculated from the data stored in the flash memory at a time of system restoration by turning on power to determine whether or not there is abnormality in the data.
As another method for data protection, an auxiliary nonvolatile memory capable of writing at higher speed than the flash memory is provided in addition to the flash memory, and the auxiliary nonvolatile memory stores bus information on a predetermined number of latest states of operation (statuses).
Operation of the electronic device shown in
The conventional electronic device including a flash memory has the data protection function as described above. In the former method of using a check sum or CRC code, a state of operation at the time of a system failure cannot be detected, and therefore a complex system needs to be constructed to perform processing for system restoration or processing for restoring the data in the flash memory.
In the latter method of storing bus information in the auxiliary nonvolatile memory, it is necessary to analyze the stored bus information, determine a state of operation at the time of a system failure, and restore the data in the flash memory according to the determined state of operation, and a complex system needs to be constructed to perform the data restoration processing.
The present invention has been made to solve problems as described above, and it is accordingly an object of the present invention to provide a nonvolatile memory and a data rewriting method of the nonvolatile memory that can readily detect a state of operation of the nonvolatile memory such for example as a NAND-type flash memory at a time of a system failure due to a power failure or the like and quickly and reliably restore the nonvolatile memory to a normal storage state.
According to the present invention, there is provided a nonvolatile memory including a physical block as a storage unit, the physical block having a data area for storing data and a redundant area for storing various management information, wherein each redundant area includes: a logical block information storing area for storing information for identifying a logical block corresponding to a physical block including the redundant area; a previously used physical block information storing area for storing information for identifying a previously used physical block, which is an immediately preceding physical block with which the corresponding logical block was associated; and a status information storing area for storing status information for distinguishing a state of operation in each stage occurring in performing data rewriting operation using the physical block including the redundant area for data writing.
With the above composition, even when a system failure occurs due to a power failure or the like, a state of operation of the physical block for writing at a time of the system failure can be detected by referring to the status information storing area, and a previously used physical block of the physical block for writing can be identified by referring to the previously used physical block information storing area. Thus, appropriate restoration processing can be performed on the physical block where the data may be destroyed and the previously used physical block of the physical block according to the state of operation. Thereby the nonvolatile memory can be restored to a normal storage state.
In the nonvolatile memory according to the present invention, the status information storing area stores at least first status information indicating that the physical block including the status information storing area is in an erased state, second status information indicating that while data writing to the physical block including the status information storing area is completed, data of the corresponding previously used physical block is not erased, and third status information indicating that data writing to the physical block including the status information storing area is completed and that the data of the corresponding previously used physical block is erased.
Further, according to the present invention, there is provided a data rewriting method of a flash memory, the data rewriting method including: a first step for determining a logical block for data rewriting; a second step for determining a physical block for data writing from among empty blocks, which are erased physical blocks allowing writing; a third step for identifying a previously used physical block, which is a physical block associated with the logical block for rewriting, by referring to an address conversion table for associating the logical block with the physical block; a fourth step for writing data to the physical block for writing; a fifth step for erasing data from the previously used physical block; and a sixth step for updating the address conversion table such that the physical block for writing is associated with the logical block for rewriting; wherein in the physical block for writing, first status information indicating that the physical block for writing is in an erased state is set initially, second status information indicating that the writing of the data is completed is set after completion of processing at the fourth step, and third status information indicating that the erasure of the data from the previously used physical block is completed is set after completion of processing at the fifth step.
With such a composition, the status information is changed at a point of change in content of restoration processing, which is required in case of a system failure, for a state of operation in each stage occurring in data rewriting operation. The nonvolatile memory can therefore be readily restored to a normal storage state by referring to the status information.
Further, in the nonvolatile memory and the data rewriting method of the nonvolatile memory according to the present invention, the first status information, the second status information, and the third status information are represented by an identical number of bits; and the second status information is formed by changing binary data of one or a plurality of bits in a bit string representing the first status information from “1” to “0”, and the third status information is formed by changing binary data of one or a plurality of bits in a bit string representing the second status information from “1” to “0”.
With such formations, in view of the status information being varied by changing binary data of one or a plurality of bits in a bit string forming the status information from “1” to “0”, even when a system failure occurred due to a power failure or the like in changing the status information and thus an abnormality occurs in which the status information does not have a proper value to be assumed, it is possible to determine whether the system failure occurred while the status information was being changed from the first status information to the second status information or whether the system failure occurred while the status information was being changed from the second status information to the third status information, by obtaining a logical product of the abnormal status information and the bit string representing the second status information and evaluating the logical product. Thus the state of operation of the nonvolatile memory can be detected in detail by the simple determination method, and the nonvolatile memory can be restored to a normal storage state quickly and reliably.
Further, in the data rewriting method of the nonvolatile memory according to the present invention, the second step for determining a physical block for data writing from among empty blocks, which are erased physical blocks allowing writing, includes: a seventh step for determining a number of empty blocks; and an eighth step for generating a random number, selecting one empty block from among a plurality of the empty blocks, and determining the selected empty block as a physical block to be written.
With such a composition, it is predicted that as the number of operations of rewriting data to the nonvolatile memory is increased, the number of operations of rewriting each physical block will be statistically equalized. Thus, the number of operations of rewriting each physical block can be equalized to thereby lengthen the life of the nonvolatile memory.
Further, in the data rewriting method of the nonvolatile memory according to the present invention, an empty block registration table including a plurality of storage units sequentially arranged so as to correspond in number with the empty blocks is provided, each of the storage units storing information for identifying an empty block, and the empty block to be written is determined by selecting one of the storage units in the empty block registration table according to the generated random number.
With such an arrangement, empty block management is facilitated. Also, each empty block can be selected with substantially the same probability only by the use of the simple method of associating empty blocks with consecutive integers given as relative addresses indicating respective storage units forming the empty block registration table and generating a random number in a predetermined numerical range according to the number of empty blocks.
Embodiments of the present invention will hereinafter be described with reference to the accompanying drawings. Incidentally, in order to clarify correspondences between elements or steps comprising an embodiment and elements or steps comprising an invention described in a claim, in the detailed description below, elements or steps Comprising an invention described in a claim which elements or steps correspond to elements or steps comprising an embodiment will be indicated by parentheses following the respective elements or steps of the embodiment as appropriate.
First Embodiment
In accessing the flash memory, as shown in
A data rewriting operation performed on the flash memory according to the present invention will next be described. A general procedure for rewriting data stored in an arbitrary logical block will first be described. First, a logical block for rewriting data is determined. Second, a search is made for an empty physical block. Third, the data for rewriting is written to the empty physical block. Fourth, data of a physical block that has been associated with the logical block to be rewritten is erased. Fifth, an address conversion table is updated so that the logical block to be rewritten is associated with the written physical block. Thus, by using the method of writing the data to the new physical block and erasing the data stored in the previously used physical block in data rewriting, even in case of a system failure due to a power failure, the system can be restored without losing management information related to the logical block to be rewritten, which information remains in either the written physical block or the previously used physical block, and also deterioration of elements due to concentrated writing to the same physical blocks can be prevented to thus lengthen the life of the flash memory itself.
Details of the data rewriting operation will next be described.
After the physical block P2 in which to write data is determined, the address P1 of the previously used physical block associated with the logical block L is determined by referring to the address conversion table (step S3 (third step)). In the physical block P2, the data is written to the data area 1; address data of the logical block L is written to the logical block address storing area 3 in the redundant area 2; address data of the immediately preceding previously used physical block P1 for erasure processing associated with the logical block L is written to the previously used physical block address storing area 4; error correction code for the address data of the logical block L and the address data of the physical block P1 is written to the first error correction code storing area 5; and error correction code for the data stored in the data area 1 is written to the second error correction code storing area 7 (step S4 (fourth step)). Status information “FFFFh” (first status information) is retained in the status information storing area 6. Incidentally, in
After the completion of the writing of the data to the physical block P2, status information “AAAAh” (second status information) is written to the status information storing area 6 to indicate the completion of the writing of the data to the physical block P2 (step S5). At this time, the same values are retained as the data of the other storing areas within the redundant area 2. Regarding the operation of writing the status information to the status information storing area 6, a state of operation in the process of the data being written to the status information storing area 6 is indicated by status 3, and a state of operation after completion of the writing of the status information “AAAAh” to the status information storing area 6 is indicated by status 4, so that these states of operation are differentiated from each other.
After the completion of the writing of the status information “AAAAh,” the data of the previously used physical block P1 is erased (step S6 (fifth step)). As described above, this erasure operation is realized by writing binary data “1” to all memory cells within the previously used physical block P1. “0→1” in
After the completion of erasure of the data from the previously used physical block P1, status information “0000h” (third status information) is written to the status information storing area 6 within the redundant area 2 of the physical block P2 to indicate the completion of erasure of the data stored in the immediately preceding previously used physical block P1 with which the logical block L was associated (step S7). At this time, the same values are retained as the data of the other storing areas within the redundant area 2. Regarding the operation of writing the status information to the status information storing area 6, a state of operation in the process of the data being written to the status information storing area 6 is indicated by status 7, and a state of operation after completion of the writing of the status information “0000h” to the status information storing area 6 is indicated by status 8, so that these states of operation are differentiated from each other. Then, in the address conversion table, the physical block associated with the logical block L is changed from the physical block P1 to the physical block P2 (step S8 (sixth step)), whereby the data rewriting operation is completed.
Description will next be made of a method of normalizing a data storing state in the flash memory, which accompanies system restoration processing performed after a system failure occurs due to a power failure, a malfunction or the like.
When the status information is not equal to “FFFFh” at the step S12, whether or not the status information is equal to “AAAAh” is determined (step S14). When the status information is equal to “AAAAh,” the writing of data to the physical block is completed, but data erasure from a previously used physical block for the physical block may not be completed. Therefore the data of the previously used physical block is erased (step S15). Also, “0000h” is written to the status information storing area 6 of the physical block (step S16). Thus, even when a system failure occurs due to a power failure or the like in the status 4, the status 5, or the status 6 shown in
When the status information is not equal to “AAAAh” at the step S14, whether or not the status information is equal to “0000h” is determined (step S17). After the step S16 and when the status information is equal to “0000h” at the step S17, a corresponding logical block is determined by referring to the logical block address storing area 3 of the searched physical block, and the searched physical block is registered as a physical block corresponding to the logical block in the address conversion table (step S18). Thereby, the address conversion table lost due to a system failure caused by a power failure or the like is reconstructed.
When the status information is not equal to “0000h” at the step S17, it is determined that the searched physical block is an abnormal block, and the address of the physical black is registered in an abnormal block table (step S19). After the step S13, after the step S18, and after the step S19, whether or not search of all physical blocks is completed is determined (step S20). When the search of all the physical blocks is not completed, the processing returns to the step S11 to perform the same processing on a next physical block. When the search of all the physical blocks is completed, the processing represented in
Conceivable factors in determination that a physical block is an abnormal block in the above search processing on all the physical blocks include a system failure due to a power failure or the like while the status information of the written physical block in the status 3 is being changed from “FFFFh” to “AAAAh,” a system failure due to a power failure or the like while the status information of the physical block being erased in the status 5 is being changed from “0000h” to “FFFFh,” and a system failure due to a power failure or the like while the status information of the written physical block in the status 7 is being changed from “AAAAh” to “0000h.” Of these factors, a system failure due to a power failure or the like while the status information of the physical block being erased in the status 5 is being changed from “0000h” to “FFFFh” can be dealt with by performing the processing at the step S15 shown in
In view of the above characteristics of the status information, at a next step, whether or not the logical product of the status information and “AAAAh” is equal to “AAAAh” is determined (step S33). When the logical product is equal to “AAAAh,” data writing to the searched physical block is completed, while erasure of data from a previously used physical block of the searched physical block is not completed. Therefore the data of the previously used physical block identified by an address stored in a previously used physical block address storing area 4 is erased (step S34). After the step S34, and when it is determined that the logical product of the status information and “AAAAh” is not equal to “AAAAh” at the step S33, “0000h” is written to a status information storing area 6 of the searched physical block (step S35). Even when a system failure caused by a power failure or the like occurs in the status 3 shown in
Next, a corresponding logical block is determined by referring to a logical block address storing area 3 of the searched physical block, and the searched physical block is registered as a physical block corresponding to the logical block in the address conversion table (step S36). By performing the processing for all the physical blocks registered as abnormal blocks, the address conversion table lost due to a system failure caused by a power failure or the like can be restored.
Next, whether search of all the physical blocks registered as abnormal blocks is completed is determined (step S37). When the search of all the physical blocks is not completed, the processing returns to the step S31 to perform the same processing on a next physical block identified on the basis of the abnormal block table. When the search of all the physical blocks is completed, the processing is ended.
As described above, in the flash memory according to the first embodiment that performs data rewriting by assigning a new physical block in an erased state to a logical block for data rewriting, writing data to the physical block, and erasing data from a previously used physical block that has been associated with the logical block, a redundant area 2 includes a logical block address storing area 3, a previously used physical block address storing area 4, and a status information storing area 6. Therefore, even when a system failure occurs due to a power failure or the like, a state of operation of a physical block being written at a time of the system failure can be detected by referring to the status information storing area 6, and a previously used physical block of the physical block being written at the time of the system failure can be identified by referring to the previously used physical block address storing area 4. Thus, appropriate restoration processing can be performed on the physical block where data may be destroyed and the previously used physical block of the physical block according to the state of operation. Thereby the flash memory can be restored to a normal storage state.
Further, status information is formed so as to have “FFFFh” indicating that the physical block is in an erased state, “AAAAh” indicating that while data writing to the physical block to be written is completed, data of a corresponding previously used physical block is not erased, and “0000h” indicating that data writing to the physical block to be written is completed and that the data of the corresponding previously used physical block is erased. Therefore, even in a case where data destruction occurs in the physical block, it suffices to erase the written physical block when the status information is “FFFFh,” and it suffices to erase the previously used physical block when the status information is “AAAAh.” The status information is thus changed at a point of change in content of restoration processing, which is required in case of a system failure, for each status occurring in data rewriting operation. The flash memory can therefore be readily restored to a normal storage state by referring to the status information.
Further, the status information of a physical block for writing is changed from “FFFFh” to “AAAAh” to “0000h” as data rewriting proceeds. Therefore, in view of the status information being varied by changing binary data of predetermined bits in a bit string forming the status information from “1” to “0,” even when a system failure occurred due to a power failure or the like in changing the status information and thus an abnormality occurs in which the status information does not have a proper value to be assumed, it is possible to determine whether the system failure occurred while the status information was being changed from “FFFFh” to “AAAAh” or whether the system failure occurred while the status information was being changed from “AAAAh” to “0000h” by obtaining a logical product of the abnormal status information and “AAAAh” and evaluating the logical product. Thus the state of operation of the flash memory can be detected in detail by a simple determination method, and the flash memory can be restored to a normal storage state quickly and reliably.
Second Embodiment
The second embodiment is different from the first embodiment in that the second embodiment has an empty block registration table for sequentially registering empty block identifying information given as an address or the like of an empty block, for example, to detect empty blocks for data writing.
A method of memory control of the second embodiment will next be described. An operation of rewriting data stored in an arbitrary logical block is basically the same as the rewriting operation represented in the flowchart of
As described above, the second embodiment has similar effects to those of the first embodiment, and also has the step S41 for determining the number of empty blocks and the step S43 for generating a random number, selecting one empty block from among a plurality of empty blocks according to the random number, and determining the selected empty block as a physical block to be written. It is therefore predicted that as the number of operations of rewriting data to the flash memory is increased, the number of operations of rewriting each physical block will be statistically equalized. Thus, the number of operations of rewriting each physical block can be equalized with a simple arrangement to thereby lengthen the life of the flash memory. Concentrated writing to the same physical blocks in a flash memory such as a NAND-type flash memory tends to deteriorate the elements, and it is therefore important to equalize the number of rewriting operations among physical blocks in order to lengthen the life of the flash memory.
In addition, since the empty block registration table 12 storing addresses of empty blocks in respective storage units sequentially arranged so as to correspond in number with the empty blocks is provided, and one empty block to be written is determined by selecting one of the storage units in the empty block registration table 12 according to a random number generated, empty block management is facilitated. Also, each empty block can be selected with substantially the same probability only by the use of the simple method of associating empty blocks with consecutive integers given as relative addresses indicating respective storage units forming the empty block registration table and generating a random number in a predetermined numerical range according to the number of empty blocks.
It is to be noted that the flash memories and the data rewriting methods of the flash memories described according to the first embodiment and the second embodiment are intended not to limit the present invention but to be illustrative of the present invention. The technical scope of the present invention is defined by claims, and various changes in design may be made within the technical scope described in the claims. For example, the status information is not limited to “FFFFh,” “AAAAh,” and “0000h.” Arbitrary bit strings may be set as the first, second, and third status information when the second status information indicating that while data writing to the physical block to be written is completed, data of a corresponding previously used physical block is not erased is formed by changing binary data of one or a plurality of bits in a bit string representing the first status information indicating an erased state from “1” to “0”, and the third status information indicating that data writing to the physical block to be written is completed and that the data of the corresponding previously used physical block is erased is formed by changing binary data of one or a plurality of bits in a bit string representing the second status information from “1” to “0”.
Nakada, Mitsuru, Tomita, Mitsuhiko
Patent | Priority | Assignee | Title |
7451266, | Apr 10 2003 | Renesas Electronics Corporation; NEC Electronics Corporation | Nonvolatile memory wear leveling by data replacement processing |
7669004, | Dec 31 2003 | SanDisk Technologies LLC | Flash storage system with write-erase abort detection mechanism |
7752175, | Oct 29 2007 | OBJECTIVITY, INC | Method, system and computer-readable media for repairing corruption of data record references |
8006030, | Mar 13 2006 | Godo Kaisha IP Bridge 1 | Memory controller for identifying the last valid page/segment in a physical block of a flash memory |
8054684, | Dec 18 2009 | SanDisk Technologies LLC | Non-volatile memory and method with atomic program sequence and write abort detection |
8055859, | Sep 13 2006 | Samsung Electronics Co., Ltd. | Apparatus and method for providing atomicity with respect to request of write operation for successive sector |
8103403, | Nov 15 2007 | Denso Corporation | Vehicular memory management apparatus |
9053809, | Nov 09 2011 | Apple Inc.; Apple Inc | Data protection from write failures in nonvolatile memory |
9424141, | Apr 28 2012 | Huawei Technologies Co., Ltd. | Hard disk data recovery method, apparatus, and system |
Patent | Priority | Assignee | Title |
5987563, | Feb 20 1992 | Fujitsu Limited | Flash memory accessed using only the logical address |
6145051, | Jul 31 1995 | U S BANK NATIONAL ASSOCIATION, AS COLLATERAL AGENT | Moving sectors within a block of information in a flash memory mass storage architecture |
6591328, | Jul 28 1998 | Sony Corporation | Non-volatile memory storing address control table data formed of logical addresses and physical addresses |
20030163631, | |||
JP11272569, | |||
JP2001147864, |
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